The mitochondnal genome of Aspergillus nidulans contains reading frames homologous to the human URFs 1 and 4

A 2830-bp segment of the mitochondrial genome of the fungus Aspergillus nidulans was sequenced and shown to contain two unidentified reading frames (URFs). These reading frames are 352 and 488 codons in length, and would specify unmodified proteins of mol. wts. 39,000 and 54,000, respectively. The derived amino acid sequences indicate that these genes are equivalent to the human mitochondrial URFs 1 and 4, with 39% amino acid homology for URF1 and 26% for URF4. Both URFs were shown by secondary structure predictions to code for predominantly beta-sheeted proteins with strong structural conservation between the fungal and human homologues. Counterparts of mammalian URFs have not previously been identified in non-mammalian genomes, and the discovery that A. nidulans possesses reading frames so closely homologous with URF1 and URF4 shows that these genes are of general functional importance in the mitochondria of diverse species.     

The sequence of the gene for cytochrome c oxidase subunit I, a frameshift containing gene for cytochrome c oxidase subunit II and seven unassigned reading frames in Trypanosoma brucei mitochrondrial maxi-circle DNA.

A 9.2 kb segment of the maxi-circle of Trypanosoma brucei mitochondrial DNA contains the genes for cytochrome c oxidase subunits I and II (coxI and coxII) and seven Unassigned Reading Frames ("URFs"). The genes for coxI and coxII display considerable homology at the aminoacid level (38 and 25%, respectively) to the corresponding genes in fungal and mammalian mtDNA, the only striking point of divergence being an unusually high cysteine content (about 4.5%). The reading frame coding for cytochrome c oxidase subunit II is discontinuous: the C-terminal portion of about 40 aminoacids, is present in the DNA-sequence in a -1 reading frame with respect to the N-terminal moiety. URF5, 8 and 10, show a low but distinct homology (about 20%) to mammalian mitochondrial URF-1, 4 and 5, respectively. In URF5, the first AUG is found at codon 145, whereas extensive homology to mammalian URF-1 sequences occurs upstream of this position. The possibility exists that UUG can serve as an initiator codon. URF7 and URF9 have a highly unusual aminoacid composition and do not possess AUG or UUG initiator codons. These URFs probably do not have a protein-coding function. The segment does not contain conventional tRNA genes.     

Nucleotide sequence of a region of the mitochondrial genome of Aspergillus nidulans including the gene for ATPase subunit 6.

A 1500 bp fragment of the Aspergillus nidulans mitochondrial genome contains genes for arginine and asparagine tRNAs, an unassigned reading frame, and the structural gene for ATPase subunit 6. The tRNA genes possess 66% nucleotide homology and possibly originated by a relatively recent duplication event. The unassigned reading frame displays a low level of homology with the human URF A6L. The predicted amino acid sequence of the A-nidulans ATPase subunit 6 gene is 40% homologous to the yeast polypeptide and includes the short, highly conserved regions also present in the equivalent subunits from other mitochondrial systems and from Escherichia coli.     

All eight unassigned reading frames of mouse mitochondrial DNA are expressed.

Animal mitochondrial DNA contains genes for 13 potential polypeptides of significant size. Five of these genes have been assigned to distinct proteins and eight remained unassigned reading frames (URFs). Short peptides corresponding to URF protein sequences were synthesized chemically. Antibodies raised to these synthetic peptides were used to establish the existence of all eight URF proteins in mouse tissues and cells by the complementary techniques of immunoperoxidase staining, protein blotting and immunoprecipitation. Immunoperoxidase staining of thin-sectioned, freeze-substituted tissue may prove generally useful for the identification of gene products for which no formal genetic data exist. Furthermore, the ability to determine the cellular and tissue distribution of such proteins may provide the first insight into their function.     

The first and fourth upstream open reading frames in GCN4 mRNA have similar initiation efficiencies but respond differently in translational control to change in length and sequence.

The third and fourth AUG codons in GCN4 mRNA efficiently repress translation of the GCN4-coding sequences under normal growth conditions. The first AUG codon is approximately 30-fold less inhibitory and is required under amino acid starvation conditions to override the repressing effects of AUG codons 3 and 4. lacZ fusions constructed to functional, elongated versions of the first and fourth upstream open reading frames (URFs) were used to show that AUG codons 1 and 4 function similarly as efficient translational start sites in vivo, raising the possibility that steps following initiation distinguish the regulatory properties of URFs 1 and 4. In accord with this idea, we observed different consequences of changing the length and termination site of URF1 versus changing those of URFs 3 and 4. The latter were lengthened considerably, with little or no effect on regulation. In fact, the function of URFs 3 and 4 was partially reconstituted with a completely heterologous URF. By contrast, certain mutations that lengthen URF1 impaired its positive regulatory function nearly as much as removing its AUG codon did. The same mutations also made URF1 a much more inhibitory element when it was present alone in the mRNA leader. These results strongly suggest that URFs 1 and 4 both function in regulation as translated coding sequences. To account for the phenotypes of the URF1 mutations, we suggest the most ribosomes normally translate URF1 and that the mutations reduce the number of ribosomes that are able to complete URF1 translation and resume scanning downstream. This effect would impair URF1 positive regulatory function if ribosomes must first translate URF1 in order to overcome the strong translational block at the 3'-proximal URFs. Because URF1-lacZ fusions were translated at the same rate under repressing and derepressing conditions, it appears that modulating initiation at URF1 is not the means that is used to restrict the regulatory consequences of URF1 translation to starvation conditions.     

Assignment of a polymorphic polypeptide to the human mitochondrial DNA unidentified reading frame 3 gene by a new peptide mapping strategy

A new method of peptide analysis is presented which allows assignment of unknown proteins to coding regions of genomes which have been sequenced. This approach involves comparison of the molecular weights of peptides generated by partial proteolytic digestion with those predicted for a protein whose primary amino acid sequence is deduced from a corresponding nucleotide sequence. The proteolytic digestions are accomplished in situ in the stacking gel of a two-dimensional polyacrylamide gel system. We have used this system to show that two variant proteins of the human mitochondrial DNA, MV-1 and MV-2, are allelic and encoded by the unidentified reading frame 3 (URF 3) gene. This assignment was supported by sequence analysis of a clone of this mtDNA region from a HeLa cell line which expresses the uncommon variant MV-2. Four nucleotide changes were found in HeLa URF 3, relative to the reported sequence from human placenta. Two of these changes alter the primary amino acid sequence of the encoded protein. It is proposed that one of those amino acid changes may account for the observed molecular weight variation in MV-1 and MV-2 by proteolytic cleavage, conformational change, or secondary modification. We have used this method to also assign a mitochondrially translated protein to URF 6. These are the first assignments of mitochondrially synthesized polypeptides to human URF genes and prove conclusively that at least some of these genes are expressed in human cells.     

Characterization of the 25-kilodalton subunit of the energy-transducing NADH-ubiquinone oxidoreductase of Paracoccus denitrificans: sequence similarity to the 24-kilodalton subunit of the flavoprotein fraction of mammalian complex I

The NADH dehydrogenase complex isolated from Paracoccus denitrificans is composed of approximately 10 unlike polypeptides [Yagi, T. (1986) Arch. Biochem. Biophys. 250, 302-311]. Structural genes encoding the subunits of this enzyme complex constitute at least one gene cluster [Xu, X., Matsuno-Yagi, A., & Yagi, T. (1991) Biochemistry 30, 6422-6428]. The 25-kDa subunit (NQO2), which has been isolated from sodium dodecyl sulfate-polyacrylamide gels, is a polypeptide of this enzyme complex. The partial N-terminal amino acid sequence and amino acid composition of the NQO2 subunit have been determined. On the basis of the amino acid sequence, the NQO2 gene was found to be located 1.7 kilobase pairs upstream of the gene for NADH-binding subunit (NQO1). The complete nucleotide sequence of the NQO2 gene was determined. It is composed of 717 base pairs and codes for 239 amino acid residues with a calculated molecular weight of 26,122. The NQO2 subunit is homologous to the Mr 24,000 subunit of the mammalian mitochondrial NADH-ubiquinone oxidoreductase which bears an electron paramagnetic resonance-visible binuclear iron-sulfur cluster (probably cluster N1b). Comparison of the predicted amino acid sequence of the Paracoccus NQO2 subunit with those of its mammalian counterparts suggests putative binding sites for the iron-sulfur cluster. In addition, nucleotide sequencing shows the presence of two unidentified reading frames between the NQO1 and NQO2 genes. These are designated URF1 and URF2 and are composed of 261 and 642 base pairs, respectively. The possible function of the protein coded for the URF2 is discussed.     

The positive regulatory function of the 5''-proximal open reading frames in GCN4 mRNA can be mimicked by heterologous, short coding sequences.

Translational control of GCN4 expression in the yeast Saccharomyces cerevisiae is mediated by multiple AUG codons present in the leader of GCN4 mRNA, each of which initiates a short open reading frame of only two or three codons. Upstream AUG codons 3 and 4 are required to repress GCN4 expression in normal growth conditions; AUG codons 1 and 2 are needed to overcome this repression in amino acid starvation conditions. We show that the regulatory function of AUG codons 1 and 2 can be qualitatively mimicked by the AUG codons of two heterologous upstream open reading frames (URFs) containing the initiation regions of the yeast genes PGK and TRP1. These AUG codons inhibit GCN4 expression when present singly in the mRNA leader; however, they stimulate GCN4 expression in derepressing conditions when inserted upstream from AUG codons 3 and 4. This finding supports the idea that AUG codons 1 and 2 function in the control mechanism as translation initiation sites and further suggests that suppression of the inhibitory effects of AUG codons 3 and 4 is a general consequence of the translation of URF 1 and 2 sequences upstream. Several observations suggest that AUG codons 3 and 4 are efficient initiation sites; however, these sequences do not act as positive regulatory elements when placed upstream from URF 1. This result suggests that efficient translation is only one of the important properties of the 5' proximal URFs in GCN4 mRNA. We propose that a second property is the ability to permit reinitiation following termination of translation and that URF 1 is optimized for this regulatory function.     

Transfer RNA genes in Drosophila mitochondrial DNA: related 5'' flanking sequences and comparisons to mammalian mitochondrial tRNA genes.

Genes for tRNAgly and tRNAserUCN have been identified within sequences of mtDNA of Drosophila yakuba. The tRNAgly gene lies between the genes for cytochrome c oxidase subunit III and URF3, and all three of these genes are contained in the same strand of the mtDNA molecule. The tRNAserUCN gene is adjacent to the URF1 gene. These genes are contained in opposite strands of the mtDNA molecule and their 3' ends overlap. The structures of the tRNAgly and tRNAserUCN genes, and of the four tRNA genes of D. yakuba mtDNA reported earlier (tRNAile, tRNAgln, tRNAf-met and tRNAval) are compared to each other, to non-organelle tRNAs, and to corresponding mammalian mitochondrial tRNA genes. Within 19 nucleotides upstream from the 5' terminal nucleotide of each of the Drosophila mitochondrial tRNAgly, tRNAserUCN, tRNAile, tRNAgln and tRNAf-met genes occurs the sequence 5'TTTATTAT, or a sequence differing from it by one nucleotide substitution. Upstream from this octanucleotide sequence, and separated from it by 3, 4 and 11 nucleotides, respectively, in the 5' flanking regions of the tRNAile, tRNAserUCN and tRNAgly genes occurs the sequence 5'GATGAG.     

Structural features of the 66-kDa subunit of the energy-transducing NADH-ubiquinone oxidoreductase (NDH-1) of Paracoccus denitrificans.

The structural gene of the Paracoccus denitrificans NADH-ubiquinone oxidoreductase encoding a homologue of the 75-kDa subunit of bovine complex I (NQO3) has been located and sequenced. It is located approximately 1 kbp downstream of the gene coding for the NADH-binding subunit (NQO1) [Xu, X., Matsuno-Yagi, A., and Yagi, T. (1991) Biochemistry 30, 6422-6428] and is composed of 2019 base pairs and codes for 673 amino acid residues with a calculated molecular weight of 73,159. The M(r) 66,000 polypeptide of the isolated Paracoccus NADH dehydrogenase complex is assigned the NQO3 designation on the basis of N-terminal protein sequence analysis, amino acid analysis, and immuno-cross-reactivity. The encoded protein contains a putative tetranuclear iron-sulfur cluster (probably cluster N4) and possibly a binuclear iron-sulfur cluster. An unidentified reading frame (URF3) which is composed of 396 base pairs and possibly codes for 132 amino acid residues was found between the NQO1 and NQO3 genes. When partial DNA sequencing of the regions downstream of the NQO3 gene was performed, sequences homologous to the mitochondrial ND-1, ND-5, and ND-2 gene products of bovine complex I were found, suggesting that the gene cluster carrying the Paracoccus NADH dehydrogenase complex contains not only structural genes encoding water-soluble subunits but also structural genes encoding hydrophobic subunits.     

Cytochrome oxidase subunit III gene in Neurospora crassa mitochondria. Location and sequence

We have located and sequenced the gene for cytochrome oxidase subunit III (CoIII) in Neurospora crassa mitochondria. The CoIII gene is located downstream from the small rRNA gene within a cluster of tRNA genes and is coded by the same strand as the tRNA and the rRNA genes. Like the tRNA and the rRNA genes, the CoIII gene is also flanked by the GC-rich palindromic DNA sequences which are highly conserved in N. crassa mitochondria. The CoIII coding sequence predicts a protein 269 amino acids long including 8 tryptophan residues. All 8 tryptophan residues are coded for by UGA. This supports our previous conclusion based on the anticodon sequence of N. crassa mitochondrial tryptophan tRNA and provides evidence for the notion that use of UGA as a codon for tryptophan rather than chain termination may be a feature common to most mitochondrial protein synthesis systems. The close correspondence between the amino acid composition of N. crassa CoIII and that of the protein predicted by the CoIII gene sequence suggests that unlike in mammalian mitochondria, AUA is a codon for isoleucine and not for methionine in N. crassa mitochondria. The N. crassa CoIII sequence shows strong homologies to the corresponding yeast and human proteins (53 and 47%, respectively). The overall hydrophobic character of the protein is consistent with suggestions that most of CoIII is embedded in the mitochondrial inner membrane.